Fluorescent Wide-Field |
100–300 |
~70°–90° |
~30 |
GI, respiratory, ear, urinary, reproductive tracts |
High imaging speed, inexpensive laser source, minimal moving parts, commercial devices exist |
Relatively low resolution and contrast, no depth sectioning |
Single-axis confocal |
0.5–5 |
0°–150° |
>2 |
GI, respiratory, ear, urinary, reproductive tracts |
High sensitivity provide functional information miniaturization through proximal or distal ends commercial devices exist |
Limited contrast and wavelength, limited tissue penetration (<100 µm), limited working distance, increased aberration due to high NA optics |
Dual-axis confocal |
3–6 |
250–1000 µm |
>15 |
Skin, GI tract, liver, head and neck, pancreas |
Effective out-of-focus rejection of scattered light for high contrast, deep tissue penetration (~400 µm), relatively isotropic resolution |
Low NA optics limits sensitivity, challenging alignment of a dual-beam configuration |
OCT |
1–15 |
2000–3000 µm |
>60 |
GI, respiratory, ear, urinary, reproductive tracts |
Impressive miniaturization, high sensitivity, dynamic range, high imaging speed, deep tissue penetration (a few mm) |
Label-free imaging, expensive detector array, Short dynamic range along depth |
Two-photon |
0.5–2 |
200–500 µm |
>5 |
GI, respiratory, tracts |
High resolution and contrast, deep tissue penetration (~500 µm ~1 mm) less photobleaching and phototoxicity, Commercial devices exist |
Relatively expensive laser source and optics, need dispersion compensation or special fibers to maintain pulse shape |
Optical resolution photoacoustic microscope (OR-PAM) |
~5 |
1000 µm |
10 |
Breast, brain |
High spatial resolution and contrast high imaging speed, deep tissue penetration (a few mm) |
Relatively expensive laser source progress on miniaturization is still ongoing |